Download QCD --- Quantum Chromodynamics

QCD --- Quantum
Chromodynamics
Outline
Outline
QCD Principles
Quantum field theory, analogy with QED
Vertex, coupling constant
Colour “red”, “green” or “blue”
Gluons
Quark and Gluon Interactions
Confinement
Asymptotic Freedom
QCD potential
QCD Experiments
Experimental evidence for
quarks, colour and gluons
e+e- annihilations
Charmonium
Scattering, DIS
Questions
Why is strong interaction short range?
Why are “free quarks” not observed?
How do quarks and gluons fragment into
hadronic jets?
Nuclear and Particle Physics
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QCD vs QED
QED
Quantum theory of electromagnetic interactions
mediated by exchange of photons
Photon couples to electric charge e
Coupling strength ∝ e ∝ √α
QCD
Quantum theory of strong interactions
mediated by exchange of gluons between quarks
Gluon couples to colour charge of quark
Coupling strength ∝ √αS
Fundamental vertices
QED
α = e2/4π ≈ 1/137
Coupling constant
QCD
αS = gS2/4π ~ 1
Strong interaction probability ∝ αS > α
Coupling strength of QCD much larger than QED
Nuclear and Particle Physics
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Colour
What is Colour ?
Charge of QCD
Conserved quantum number
“Red”, “green” or “blue”
Quarks
Come in three colours
rgb
Anti-quarks have anti-colours r g b
Leptons, other Gauge Bosons - γ, W±, Z0
Don’t carry colour, “zero colour charge”
Î Don’t participate in strong interaction
Caveat
“… colour is not to be taken literally.”
Interaction
QED
QCD
Conserved
charge
electric
charge e
colour charges
r, g ,b
Coupling
constant
α = e2/4π
αS = gS2/4π
Gauge boson Photon
8 gluons
Charge
carriers
quarks
gluons
Nuclear and Particle Physics
fermions
(q ≠ 0)
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Gluons
Gluon Properties
Gluons are massless spin-1 bosons
Î QCD propagator 1/q2
Emission or absorption of gluons by quarks
changes colour of quarks - Colour is conserved
Î Gluons carry colour charge themselves
e.g. rg gluon changes red quark into green
QCD very different from QED, q(photon) = 0
Number of gluons
Naively expect 9 gluons
rb, rg, gb, gr, br, bg, rr, gg, bb
Symmetry -> 8 octet and 1 singlet states
Î 8 gluons realised by Nature (colour octet)
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Quark & Gluon
Interactions
Quark-Antiquark Scattering
describes a meson
e.g. π+ = (u-dbar)
Single gluon exchange
at short distance ≤ 0.1 fm
QCD Potential
at short distance ~ 0.1 fm
attractive - negative sign
QED-like apart from colour factor 4/3
More than one gluon -> colour factor
VQCD ( r ) = −
4 αS
3 r
Gluon Self-Interactions
QED versus QCD
- So far pretty similar
Photons and gluons – massless spin-1 bosons
Big difference
- gluons carry colour charge
Î Gluons interact with each other
3-gluon vertex
4-gluon vertex
Î Origin of huge differences
between QCD and QED
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Confinement
Experimental Evidence
Do not observe free quarks
Quarks confined within hadrons
Strong Interaction Dynamics
Gluons attract each other - self-interactions
Î Colour force lines pulled together in QCD
Colour Force
between 2 quarks at “long” distances O(1 fm)
String with tension k -> Potential V(r) = kr
Stored energy/unit length is constant
Separation of quarks
requires infinite amount of energy
Confinement
Direct consequence of gluon self-interactions
Particles with colour - quarks and gluons confined inside QCD potential, must combine
into hadrons with zero net colour charge
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QCD Potential
Mesons
quark-antiquark pair
colour wave fct.
with zero net colour charge
Single gluon exchange -> colour of individual
rr → rr
rr → bb
q or anti-q can change
QCD potential
VQCD ( r ) = −
4 αS
+ kr
3 r
QED-like at short distance r ≤ 0.1 fm
Quarks are tightly bound
αS ≈ 0.2 .. 0.3
String tension -> Potential increases linearly
at large distance
r ≥ 1 fm
αS = 0.2
k = 1 GeV/fm
Potential similar
for quarks in
baryons
Force
Between two quarks at large distance
F = |dV/dr| = k = 1.6 10-10 J/ 10-15 m = 16000 N
Equivalent to weight of large car
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Coupling Constant αS
Properties
αS --- coupling strength of strong interaction
Recall QED - coupling constant varies
with distance - running α
In QED – bare electron charge is screened by
cloud of virtual e-e+ pairs
In QCD – similar effects
QCD Quantum Fluctuations
Cloud of virtual q-anti-q pairs around a quark
Î Screening of colour charge
Colour charge decreases with distance
Cloud of virtual gluons --- no equivalent in QED
due to gluon self-interactions
Colour charge of gluons contributes to
effective colour charge of quark
Î Anti-screening of colour charge
Colour charge increases with distance
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Running of αS
Screening and Anti-screening
Anti-screening dominates
Effective colour charge increases with distance
At large distances / low energies αS ~ 1 - large
Higher order diagrams -> αS increasingly larger
Summation of diagrams diverges
Perturbation theory fails
Asymptotic
Asymptotic Freedom
Freedom
α S (q 2 ) =
αS (µ 2 )
⎛
Coupling constant
q2 ⎞
2
⎜⎜ 1 + β α S ( µ ) ln 2 ⎟⎟
µ ⎠
2
2
⎝
αS = 0.12 at q = (100 GeV)
11n − 2 f
small at high energies
β=
12π
Running of αS
depends on q2 and # of colours and flavours
Energetic quarks are (almost) free particles
Summation of all diagrams converges
QCD Perturbation theory works
n = 3 colours
f=3…6
flavours
Nobel prize 2004
Gross, Politzer, Wilczek
Nuclear and Particle Physics
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Hadronisation & Jets
What happens when quarks separate?
e + e − → qq annihilation
Example:
Quarks separate
Estring increases - when Estring > 2 mq
String breaks up into qq pairs - fragmentation
Hadronisation
As energy decreases
Formation of hadrons
(mesons and baryons)
Hadrons follow direction
of original qq
LEP
√s =
91 GeV
Nuclear and Particle Physics
Jets
e + e − → qq
hadronisation
e + e − → hadrons
Observe collimated jets
back-to-back
in CoM frame
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e+e- Annihilation
Feynman Diagrams
e + e − → qq and e + e − → µ − µ −
Quark and muon masses are neglected
Only difference in coupling of virtual photon to
final state fermion pair is charge Qf
muons Qµ = ±1
µ µ
+
quarks Qq = ±2/3
qq
or ±1/3
−
Cross section
For a single quark flavour --- without colour
expect cross section ratio
Qq
σ (e + e − → qq )
Rq =
=
= Qq2
+ −
+ −
2
σ (e e → µ µ ) Qµ
2
With colour – each quarks has NC = 3 final states
Rule is to sum over all available final states
σ (e + e − → qq )
Rq =
= N C Qq2 = 3Qq2
+ −
+ −
σ (e e → µ µ )
Hadronisation
Measure e + e − → hadrons not
e + e − → qq
qq -pairs fragment and form hadronic jets
Jets from different qq -pairs are similar
compared
to quark masses
Nuclear at
and high
Particleenergies
Physics
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e+e- Annihilation
σ (e + e − → hadrons )
R=
= 3∑q Qq2
+ −
+ −
σ (e e → µ µ )
Ratio R
Sum is over all quark flavours (u, d, s, c, b, t)
kinematically accessible at CoM energy, √s, of
collider, and 3 colours (r,g,b) for each flavour
R
(
R
(
R
(
⎛ ⎛ 2 ⎞2 ⎛ − 1 ⎞2 ⎛ − 1 ⎞2 ⎞
⎟=2
= 3 ⎜⎜ ⎟ + ⎜
+
⎜ ⎝ 3 ⎠ ⎝ 3 ⎟⎠ ⎝⎜ 3 ⎟⎠ ⎟
⎠
⎝
2
2
2
⎛ ⎛ 2 ⎞ ⎛ − 1 ⎞ ⎛ − 1 ⎞ ⎛ 2 ⎞ 2 ⎞ 10
⎟=
+
+
s > 2mc ~ 3 GeV = 3 ⎜ ⎜ ⎟ + ⎜
⎜ ⎝ 3 ⎠ ⎝ 3 ⎟⎠ ⎜⎝ 3 ⎟⎠ ⎜⎝ 3 ⎟⎠ ⎟ 3
⎝
⎠
2
2
2
2
⎛ ⎛ 2 ⎞ ⎛ − 1 ⎞ ⎛ − 1 ⎞ ⎛ 2 ⎞ ⎛ − 1 ⎞ 2 ⎞ 11
⎟=
+
+
+
s > 2mb ~ 10 GeV = 3 ⎜ ⎜ ⎟ + ⎜
⎜ ⎝ 3 ⎠ ⎝ 3 ⎟⎠ ⎜⎝ 3 ⎟⎠ ⎜⎝ 3 ⎟⎠ ⎜⎝ 3 ⎟⎠ ⎟ 3
⎝
⎠
s > 2m s ~ 1 GeV
)
u, d , s
)
u, d , s , c
)
u, d , s , c , b
Measurements
R
u,d,s,c
u,d,s
u,d,s,c,b
No colour
√s
R increases in steps with √s
R ≈ 3.85 ≈ 11/3 at √s ≥ 10 GeV
Î Overwhelming evidence for colour
√s < 10 GeV -- resonances (c-cbar and b-bar)
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Charmonium
Discovery of Charm Quark
1974 Brookhaven and SLAC
Narrow resonance at 3.1 GeV
decays into e+e-, µ+µ-, hadrons
did not fit in existing schemes
p Be → e + e − X
J/ψ Meson
Mass mJ/ψ = 3.1 GeV/c2
Narrow width, smaller than
experimental resolution
Total width Γ = 0.087 MeV
Lifetime τ = ħ/Γ = 7.6 ·10-21 s
= 1000 x expected for
strong interaction process
e + e − → qq
Branching Fraction
J/ψ decays
many final states with
partial decay width Γi
Total decay width
e+e− → µ + µ −
Γ = ∑ i Γi
Branching fraction
e+e− → e+e−
Γi
Γ
B( J / ψ → qq ) = (87.7 ± 0.5)%
Bi =
B( J / ψ → µ + µ − ) = (5.88 ± 0.10)%
. B( J / ψ
→ e + e − ) = (5.93 ± 0.10)%
Nuclear and Particle Physics
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Charmonium
Quark Model Explanation
J/ψ is new quark (c-cbar) bound state
Strong decay for J/ψ (diagram b) is forbidden
by energy conservation at √s =mJ/ψ < 2mD
Allowed transition (diagram a) has three gluons
Decay rate suppressed ∝ αS6
J/ψ =ψ(1S) resonance established quarks
as real particles
Excited Charmonium states
Found more states
ψ(2S), ψ(3S)
e.g.ψ ( 2 S ) → J /ψπ +π −
J /ψ → e + e −
ψ states - spin J = 1 (like γ)
Observe also ηc (J = 0)
and P states χc (L = 1)
In agreement with
QCD potential calculations
Similar to positronium (e+e-)
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Evidence for Gluons
Quarks radiate Gluons
2nd order diagram
e + e − → qq g
Experimental Signature
Gluons confined, fragments
hadronises into jet
Î 3-jet events
JADE √s = 35 GeV
LEP √s = 91 GeV
Measurement of αS
When including gluon radiation
additional factor √αS in matrix element
adds term with factor αS in cross section
σ (e + e − → hadrons )
⎛ α ⎞
R=
= 3∑q Qq2 ⎜ 1 + S ⎟
+ −
+ −
σ (e e → µ µ )
π ⎠
⎝
e.g R(q2 = (25 GeV)2) ≈ 3.85 > 11/3 → αS = 0.15
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Running of αS
Measurements
at many energies √s = 1.5 GeV to 200 GeV
e+e- Annihilations
Ratio R ∝ (1+αS/π)
Ratio of 3 jet versus 2 jet events ∝ αS
Event shapes - angular distributions
Hadronic collisions
Deep Inelastic scattering
Charmonium and Upsilon
Tau decays
Lattice QCD calculations
Î αS is running
αS (MZ) = 0.1187 ± 0.002
Many methods
Nuclear and Particle Physics
e+e- annihilation
Franz Muheim
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Evidence for Colour
Ratio R
Discussed in previous slides
∆++ Baryon
Strong interaction resonance - spin 3/2
Quark model explains ∆++ as (uuu)
Wave function for (u↑u↑u↑) is symmetric
under interchange of identical quarks
Appears to violate Pauli Principle
Î Led to introduction of colour
1964 Greenberg
Antisymmetric colour wave function for baryons
Same arguments for ∆- (ddd) and Ω- (sss)
Decay rate π0 → γγ
Γ(π0 → γγ) ∝ N2colour
Measurement:
Ncolour = 2.99 ± 0.12
Nuclear and Particle Physics
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Elastic e-p Scattering
e-p → e-p
Probe structure of proton with electron beam
Kinematics
Laboratory frame, proton at rest
r
ν
,
q
Energy and momentum transfer
ν = E1 − E 3
(q + p2 )2 =
p42
q 2 + M 2 + 2 p2 ⋅ q = M 2
r
q µ = (ν , q )
r
r
p2 ⋅ q = M ,0 ⋅ (ν , q ) = Mν
(
)
⇒ q 22 = −2 Mν < 0
q2 and ν not independent, E3 and scattering
angle θ related, only need to measure E1 and θ
Cross Section
dσ dσ
=
F q2
dΩ dΩ point
Form factor F(q2)
describes deviation
from a point charge
F(q2)
F(q2) is
Fourier transform of
charge distribution
inside proton,
see Nuclear Physics
Nuclear and Particle Physics
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18
-q2
Deep Inelastic Scattering
e-p → e-X Scattering
At high |q2| proton breaks up into hadrons
W 2 = q 2 + M 2 + 2 p2 ⋅ q ≠ M 2
−qq22
−
xx == 2 Mν
2 Mν
q2 and ν independent, hadronic mass W
define dimensionless variable x with 0 < x < 1
Form factor F(q2) → Structure function F2(ν, q2)
Experimental Results
Inelastic cross section
independent of q2
dependent on x → F2 (x)
Evidence for point-like
particles inside proton
F2
Partons
Point-like constituents inside nucleons
-q2
Feynman
− q2
q2
m
=0 ⇒ x=
=
ν+
2m
2 Mν M
r
m 2 = x 2 E 22 − x 2 p22 = x 2 M 2
electron scatters off “free” parton with mass m
x is fraction of proton 4-momentum
Nuclear and Particle Physics
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Partons
Parton Distribution Functions fi(x)
Probability that parton i carries fraction x
of particle momentum
i = u,d,s (valence quarks), sea quarks, gluons
Require ∑ ∫ x f i ( x )dx = 1
i
Quarks carry only 54% of proton momentum
Gluons carry
remaining 46%
Î Partons are
quarks and gluons
Quark- Quark
Scattering
2 jet events at p-pbar collider √s = 315 GeV
|q2| ≈ 2000 GeV2
see QCD points
M∝
⇒
αS αS
q2
dσ
α S2
∝
dΩ sin 4 (θ / 2 )
QED points are
Geiger & Marsden (1911)
Rutherford scattering
Nuclear and Particle Physics
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